Oxidation catalyst containing molybdenum oxide,tellurium oxide and a copper phosphate



United States Patent OXIDATION CATALSi'ST ,CONTAINING MOLYB- DENUM OXIDE, TELLURIUM OXIDE AND A COPPER PHOSPHATE Jamal S. Eden, Akron, Ohio, assignor to The B. F. Good- US. Cl. 252437 4 Claims ABSTRACT OF THE DISCLOSURE Useful oxidation catalysts for preparing unsaturated aldehydes and unsaturated carboxylic acids by oxidation of unsaturated hydrocarbons at an elevated temperature comprise molybdenum oxide, tellurium oxide and a copper phosphate.

This is a division of application Ser. No. 522,032, filed Jan. 21, 1966, now US. Pat. 3,493,608.

This invention relates to new 'and useful catalysts and to a method of preparing unsaturated aldehydes and unsaturated carboxylic acids by oxidation of unsaturated hydrocarbons at an elevated temperature, and relates more particularly to catalysts comprising a mixture of a molybdenum oxide, tellurium oxide and a copper phosphate in a molar ratio of 100 M00 -100 TeO and 10l00 of a copper phosphate and to a method of preparing acrolein and acrylic acid, or methacrolein and methacrylic acid by passing vapors of propylene or isobutylene and an oxygen-containing gas over the catalyst at a temperature of from about 325 C. to about 550 C. The catalyst can also be designated as with the P preferably being in the form of a phosphate, i.e., each P is attached to 3 or 4 oxygen atoms.

Numerous attempts have been made in the past to prepare products of higher oxidation state from hydrocarbons, especially from the normally gaseous hydrocarbons. However, prior catalysts and procedures for oxidizing monoolefinic gaseous hydrocarbons to monoolefinically unsaturated aldehydes or monoolefinically unsaturated carboxylic acids with the same number of carbon atoms as the hydrocarbon having short-comings. The catalysts either have a very short active life, or they convert only a portion of the hydrocarbon to desired end groups per pass; they oxidize the hydrocarbon excessively to form high proportions of carbon monoxide or carbon dioxide or both; they are not sufficiently selective, so that the hydrocarbon molecule is attacked at both the olefinic unsaturation and at a methyl group; or the oxidation of the olefin does not proceed beyond the aldehyde stage.

It is, therefore, unexpected to find a catalyst having unusually long life that will convert a substantial amount, more than 50% per pass, of a gaseous monoolefin such as propylene or isobutylene to yield very high proportions of acrolein and acrylic acid, or methacrolein and methacrylic acid. It is also unexpected to find a catalyst that produces a wide ratio of olefinic aldehyde to monoolefinically unsaturated carboxylic acid by controllable changes in reaction conditions or catalyst composition at good mol percent efficiencies for the aldehyde and unsaturated vide means for obtaining a product mix that is needed at any particular time during commercial operation.

THE REACTANTS The essential reactants are (l) propylene or isobutylene and (2) an oxygen-containing gas, which can be pure oxygen, oxygen diluted with an inert gas, oxygen enriched air or air without additional oxygen. For reasons of economy, air is the preferred oxygen-containing reactant.

For the purpose of this invention the hydrocarbons which are oxidized can be defined generically by the formula H (OHM-1 CH3-C=CH2 wherein it is also apparent that the end products formed result from the oxidation of only one methyl group on the hydrocarbon molecule while the terminal CH =C remains intact.

Stoichiometric ratios of oxygen to olefin for the purpose of' this invention are 1.5 to 1. Slightly lower amounts of oxygen can be used as a sacrifice of yield. It is preferred, however, to use 33 to 66% excess oxygen. Larger excesses do not impair the yields of aldehydes and acids, but for practical considerations an excess much above would require extremely large equipment for a given production capacity.

The addition of steam into the reactor along with the hydrocarbon and oxygen-containing gas is desirable but not absolutely essential. The function of steam is not clear, but it seems to reduce the amount of carbon monoxide and dioxide in the effluent gases.

Other diluent gases can be used. Surprisingly, saturated hydrocarbons such as propane are rather inert under the reaction conditions. Nitrogen, argon, krypton or other known inert gases can be used as diluents if desired but are not preferred because of the added cost.

THE CATALYST AND ITS PREPARATION There are several methods for the preparation of the catalyst, which can be supported or unsupported. It is possible to dissolve each of the starting ingredients in water and combine them from the aqueous solutions or the ingredients can be dry blended. Because of the more uniform blend obtained by the solution procedure, it is preferred.

The general procedure for preparing a catalyst from water-soluble ingredients is to dissolve the requisite amount of molybdenum salt, a tellurium salt and a copper salt in water. Add the requisite amount of phosphoric acid to the copper salt solution. Add the tellurium salt solution to the molybdenum salt solution and then add the copper salt-phosphoric acid mixture to the molybdenum-tellurium salt mixture. The catalyst is then dried and baked at 400 C. for about 16 hours.

Supported catalysts can be prepared by adding a dry support or an aqueous slurry thereof to the aqueous solution of catalyst or the aqueous catalyst ingredients can be added to the slurry of the support.

Alternatively a slurry of the catalyst ingredients can be prepared in water, then dried and baked. For supported catalysts the aqueous slurry of the catalyst ingredients can be added to an aqueous suspension of the support or vice versa, and then dried and baked.

Another method is to blend the dry ingredients of the desired particle size and then mix them thoroughly. Thorough blending and uniform particle size is desired.

A specific example of the solution method is now set forth.

(1) Dissolve 52.98 g. of ammonium molybdate in 100 ml. of water and add to 100 g. of an aqueous colloidal dispersion of microspheroidal silica in a concentration of 30-35% SiO (Ludox HS.)

(2) 15.96 g. of TeO dissolved in 40 ml. of concentrated HCl is added to (1).

(3) Dissolve 34.1 g. of CuCl -2H O in 50 ml. of water and add 23.1 g. of 85% H PO Add this mixture slowly to the mixture of (1) and (2).

Dry on a steam bath and bake for 16 hours at 400 C. Thereafter, the catalyst is ground to the desired mesh size and sieved.

Among the suitable supports are silica, silica-containing materials, such as diatomaceous earth, kieselguhr, silicon carbide, clay, aluminum oxides and even carbon, although the latter tends to be consumed during the reaction.

The exact chemical structure of the catalysts made by the above procedures is not known, but catalysts with molar ratios of 100 Mo, 10-100 Te and 10-100 of a copper phosphate can be used for oxidizing the monoolefinic hydrocarbon to aldehyde and/or carboxylic acid. The catalyst contains chemically bound oxygen so that the generic formula can be written as MoO 100TeO 10-10OCu P O or other copper phosphate The phosphate can be a P0,, radical, a pyrophosphate, or a polyphosphate.

REACTION CONDITIONS The reaction. can be carried out in either a fixed or fluidized catalyst bed.

The reaction temperature can range from about 300 to 450 C. for the oxidation of propylene but the preferred range is from about 350 to about 425 C. Below 350 C. the conversion per pass is lower and low temperature tends to produce more aldehyde than desired. Usually, a longer contact time is needed at lower temperatures to obtain the yields of desired products obtainable at higher temperatures. Above 425 C. in the propylene oxidation some the desired end products appear to be oxidized to carbon oxides. This is much more apparent at 450 C. For isobutylene, oxidation temperatures of 375-550 are desirable with the preferred range being 300-450 C.

The molar ratio of oxygen to propylene or isobutylene should be at least 2 to 1 for good conversion and yields. Some excess oxygen, 33 to 66 mol percent is even more desirable and is preferred. There is no critical upper limit as to the amount of oxygen, but when air is used as the oxygen-containing gas it becomes apparent that too great an excess will require large reactors, pumping, compressing and other auxiliary equipment for any given amount of desired end product. It is therefore best to limit the amount of air to provide a 33 to 66% excess of oxygen. This range provides the largest proportion of acid, under given reaction conditions. Also, since care is needed to avoid an explosive mixture, the limiting of air aids in that direction.

The molar ratio of steam to propylene or isobutylene can range from 0 to about to 7, but best results are obtained with molar ratios of about 3 to 5 per mol of olefin and for this reason are preferred.

The contact time can vary considerably in the range of about 2 to 70 seconds. Best results are obtained in a range of about 8 to 54 seconds and this range is preferred. Longer contact times usually favor the production of acid at any given temperature.

The particle size of catalyst for fixed bed operations used is from 1018 mesh. As is known, for fixed beds, the size may be of a wider range particle size. For fluid bed systems the catalyst size should be from 80-325 mesh (U.S. Sieve).

The reaction can be run at atmospheric pressure, in a partial vacuum or under induced pressure up to 50100 p.s.i. Atmospheric pressure is preferred for fixed bed Sys- Cit tems and a pressure of l to 100 p.s.i. for fluid bed reactions. Operation at a pressure which is below the dew point of the unsaturated acid at the reaction temperature is advantageous.

The data in the examples show that wide variations in percentges of unsaturated acids and aldehydes can be obtined with s ingle catalyst, using fixed ratio of rectants but changing the temperature and/or contact time. Further variation is obtainable by controlling the other variables in the reaction including the catalyst compositions within the limits set forth herein.

The examples are intended to illustrate the invention but not to limit it.

THE EXAMPLES A series of runs was made in a fixed bed reactor of a high silicoa (Vycor) glass tube 12 inches long and 30 mm. outer diameter. The reactor had three inlets, one for air, one for steam and one for propylene. Three external electrically operated heating coils were wound on the reactor. One of the coils extended along the entire length of the reactor and each of the remaining coils extended only about one half the length of the reactor.

Outlet vapors were passed through a short water cooled condenser. Uncondensed gases were passed through a gas chromatograph (PerkinElmer model 154D) and analyzed continuously. The liquid condensate was weighed and then analyzed for acrylic acid and acrolein in the gas chromatograph.

The reactor was filled with ml. of a catalyst made by the solution method described above, using a ratio of 75 M00 15 TEO and 25 Cu P O Empirically the catalyst is MOTC 3CU P2 504g and the P is present as P O The catalyst had a mesh size of 10-18 (U.S. Sieve).

Steam at a temperature of ZOO-250 C. was first passed into the reactor. Then propylene and air were separately fed into the stream of water vapor. This mixture then passed through a pre-heater and entered the reactor at about 200235 C. The reactor was pre-heated to about 285 C. before the gas feed was begun.

The ratio of reactants was about 2.52 mols of oxygen and 3.88 mols of steam per mol of propylene. Cold contact time was 18.5 seconds. The table below summarizes the data obtained in these runs:

1. A catalyst composition consisting essentially of molybdenum oxide, tellurium oxide and a copper phosphate in a molar ratio of 100 molybdenum oxide, 10-100 tel-.

lurium oxide and 10-100 of a copper phosphate.

2. The composition of claim 1 wherein the copper phosphate is copper pyrophosphate.

3. The composition of claim 2 wherein the molar ratio is about 75 M00 15 TeO and 25 Cu P O 4. The composition of claim 1 on a silicic support.

References Cited UNITED STATES PATENTS 3,192,259 6/1965 Fetterly et a1 252437X 3,236,782 2/1966 Koch 260-604X 3,451,945 6/1969 Eden 252437 PATRICK P. GARVIN, Primary Examiner 

